KR20210014977A - Rotor rolling system for generator - Google Patents

Abstract

Provided is a generator rotor rolling system which comprises: an active support supporting one side of a collector ring of a rotor; and a passive support supporting the other side of the collector ring, wherein the active support includes an active lower frame supporting two spaced apart active supporting rollers and an active upper frame mounted to receive a rotor in an inverted U-shape on an upper portion of the active lower frame, and the passive support includes a passive lower frame supporting two spaced apart passive supporting rollers and a passive upper frame mounted to receive the rotor in the inverted U-shape on an upper portion of the passive lower frame. Therefore, construction cost and period can be shortened.

Description

Generator rotor rolling system {ROTOR ROLLING SYSTEM FOR GENERATOR}

The present invention relates to a rolling system for preventing deformation of a generator rotor, and more particularly, to a generator rotor rolling system capable of processing a rotor in the field to prevent a touch or deformation of the rotor of the generator. will be.

The generator largely includes a stator and a rotor. In general, a power generation facility is manufactured in a large size, and since the rotor rotates at high speed in the power generation facility, if a mechanical defect or deformation occurs in the rotor, it is highly likely to lead to a major accident.

However, in general, when the power generation facility is planned and maintained, the rotor of the generator can be separated and stored. If the rotor is left outside for a long time, shaft deformation may occur due to the load on the shaft.

In addition, when abrasion of the generator collector ring occurs, a large rotor must be taken out of the power generation facility for maintenance. In this case, emergency construction is difficult, which may cause a problem in facility reliability.

During the Class A planned preventive shutdown period, the turning gear is stopped, the rotor is taken out to the outside, and stored, and if an imbalance occurs on the surface of the collector ring of the rotor, it is also taken out to perform maintenance work.

Therefore, after separating the rotor from the generator, the need for a system capable of preventing axial deformation of the rotor and capable of field processing has emerged.

The present invention provides a generator rotor rolling system capable of preventing axial deformation of the rotor due to winding stress after separating the rotor from the generator or turbine.

The present invention provides a generator rotor rolling system for easy seating and fixing of the rotor so that the rotor can be processed directly on site when the collector ring needs to be processed, and for shortening construction cost and time.

According to an exemplary embodiment of the present invention for achieving the above-described objects of the present invention, the generator rotor rolling system includes an active support for supporting one side of the collector ring of the rotor and a passive support for supporting the other side of the collector ring. The active support includes an active lower frame supporting two spaced apart active support rollers, and an active upper frame seated to receive the rotor in an inverted U-shape above the active lower frame, and the passive support includes two spaced apart. And a manual lower frame for supporting the manual support roller and a manual upper frame seated to receive the rotor in an inverted U-shape at the top of the manual lower frame.

Two first stabilizing rollers are provided at the lower part of the active upper frame to press the upper part of one side of the rotor in response to the active support roller, and at the lower part of the passive upper frame, the upper part of the other side of the rotor is pressed against the passive support roller. Two second stabilizing rollers may be provided.

The active lower frame may include a drive motor and two belts that transmit rotational force from the drive motor to rotate the two active support rollers in the same direction.

The axial deformation can be prevented by rotating the rotor in a variable manner from 0 rpm to 50 rpm or less by the drive motor, and the manual support allows the support position of the manual support roller and the second stabilizer roller to range from 0 to 150 mm in the axial direction of the rotor. Can be provided to enable adjustment in.

The generator rotor rolling system of the present invention can prevent axial deformation of the rotor due to winding stress after separating the rotor from the generator or turbine.

In addition, the stand variable type can be used for maintenance of the rotor with a standardization power of about 500MW or more, and by precisely adjusting the rotation speed of the rotor in the range of about 0-50 rpm, the axis of the rotor is prevented from deforming and can be set according to the field situation. I can.

The generator rotor rolling system of the present invention facilitates the seating and fixing of the rotor so that the rotor can be processed directly on site when the collector ring needs to be processed, and construction cost and time can be reduced.

1 is a view for explaining a generator rotor rolling system according to an embodiment of the present invention.
FIG. 2 is a partially enlarged view to specifically describe the active support and the passive support of the generator rotor rolling system of FIG. 1.
3 is a view for explaining a coupling relationship of the generator rotor rolling system of FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, but the present invention is not limited or limited by the embodiments. For reference, in the present description, the same numbers refer to substantially the same elements, and contents described in other drawings under the above rules may be cited and described, and contents that are determined to be obvious to those skilled in the art or repeated may be omitted.

1 is a view for explaining a generator rotor rolling system according to an embodiment of the present invention, FIG. 2 is a partially enlarged view to specifically describe the active support and the passive support of the generator rotor rolling system of FIG. 3 is a diagram for explaining a coupling relationship between the generator rotor rolling system of FIG. 1.

1 to 3, the generator rotor rolling system is for supporting the rotor 10 separated from the generator, and includes an active support 110 and a passive support 140. The active support 110 may support the rotor 10 at one side of the rotor 10 and provide a driving force for rotating at the same time, and the passive support 140 may provide a driving force for rotating the rotor 10 at the other side of the rotor 10. 10), and can passively support the rotation of the rotating rotor 10 by the active support 110.

Specifically, the active support 110 is located on one side with the center of the collector ring of the rotor 10, and the active lower frame 120 and the active lower part supporting the rotor 10 under one side of the rotor 10 It may include an active upper frame 130 covering the upper portion of the frame 120 in an inverted U-shape or a C-shape.

On the upper part of the active lower frame 120, two spaced active support rollers 122 are provided symmetrically left and right around the center, and the two active support rollers 122 are the shaft diameter of the rotor 10 It is spaced smaller than that to support the axis of the rotor 10 and at the same time transmit a force capable of rotating about 0 to 50 rpm.

In addition, the active upper frame 130 is formed in an inverted U-shape or a c-shape, and the two legs may be fastened to the left and right of the active lower frame 120. In addition, the inner surface of the active upper frame 130 may be equipped with two first stabilizing rollers 132 capable of pressing the shaft of the rotor 10 from the upper surface. The first stabilizing roller 132 may rotate passively in response to the rotation of the rotor 10, and press one side of the rotor 10 so that the rotor 10 rotates without shaking.

The active lower frame 120 may have a built-in drive motor 126 for rotating the rotor 10, and the rotating shaft of the drive motor 126 is actively supported through two belts 124 through pulleys or sprockets. It may be connected to the roller 122.

In the present embodiment, a combination of a pulley and a belt is provided, but in addition to this, the driving force can be transmitted in various ways using a combination of a sprocket and a chain, a combination of a timing pulley and a timing belt, a gear box, and the like.

Referring to Figure 2 (a), the generator rotor rolling system according to the present embodiment may further include a control unit 170 capable of variably controlling the rotation of the drive motor 126, the user can control the control unit 170 It is possible to control the rotational speed of the rotor 10 as designed through the panel or software adjustment.

However, the weight of the rotor 10 is heavy, and since sliding between the active support roller 122 and the rotor 10 may occur, the controller 170 measures the rotational speed of the rotor 10 in real time. It may further include a sensor 172 for.

Accordingly, the control unit 170 can compare the rotation control command of the driving motor 126 by pulse control and the like and the actual rotation speed of the rotor 10 according to the control in real time, and compare the results with each other to compare the driving motor ( 126) can be variably controlled by feeding back the rotation.

Opposing the active support 110, the passive support 140 is located on the other side with the center of the collector ring of the rotor 10, and a passive lower frame that supports the rotor 10 under the other side of the rotor 10 150 and a passive upper frame 160 covering the upper portion of the passive lower frame 150 in an inverted U-shape or a c-shape.

On the upper part of the manual lower frame 150, two spaced manual support rollers 152 are provided symmetrically left and right around the center, and the two manual support rollers 152 are the shaft diameter of the rotor 10 Smaller spaced apart to support the shaft of the rotor 10, and at the same time varying about 0 ~ 50rpm is engaged with the rotating rotor to support the rotor 10 to rotate smoothly.

In addition, like the active upper frame 130, the passive upper frame 160 is also formed in an inverted U-shape or a c-shape, and the two legs may be fastened to the left and right of the passive lower frame 150. In addition, on the inner surface of the manual upper frame 160, two second stabilizing rollers 162 that can press the shaft of the rotor 10 from the upper surface may be mounted. The second stabilizing roller 162 may also be rotated passively in response to the rotation of the rotor 10, and by pressing one side of the rotor 10, the rotor 10 may rotate without shaking.

In addition, the manual support 140 may be provided so that the support position supported by the manual support roller 152 and the second stability roller 162 can be adjusted in a range of about 0 to 150 mm with respect to the axial direction of the rotor 10. In some cases, the angle can be adjusted by about 0 to 3 degrees. Through such fine adjustment, the rotor 10 can be accurately fixed.

As described above, although it has been described with reference to preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention without departing from the spirit and scope of the present invention described in the following claims. You will understand that you can do it.

110: active support 120: active lower frame
122: active support roller 124: belt
126: drive motor 130: active upper frame
132: first stability roller 140: manual support
150: manual lower frame 152: manual support roller
160: manual upper frame 162: second stability roller
170: control unit 172: sensor

Claims (7)

In the generator rotor rolling system,
An active support for supporting one side of the collector ring of the rotor and a passive support for supporting the other side of the collector ring,
The active support includes an active lower frame for supporting two spaced apart active support rollers, and an active upper frame seated to receive the rotor in an inverted U-shape above the active lower frame,
The manual support includes a manual lower frame supporting two spaced apart manual support rollers, and a manual upper frame seated to receive the rotor in an inverted U-shape above the manual lower frame. Rolling system. The method of claim 1,
Two first stabilizing rollers are provided at a lower portion of the active upper frame to press the upper portion of one side of the rotor in response to the active support roller, and a lower portion of the passive upper frame is provided with the rotor Generator rotor rolling system, characterized in that provided with two second stabilizing rollers for pressing the other side of the upper. The method of claim 1,
The active lower frame comprises a drive motor and two belts transmitting rotational force for rotating the two active support rollers in the same direction from the drive motor. The method of claim 3,
Generator rotor rolling system, characterized in that to prevent shaft deformation by rotating the rotor in a variable type by the drive motor to more than 0rpm 50rpm or less. The method of claim 4,
Generator rotor rolling system comprising a control unit capable of variably controlling the rotation of the drive motor. The method of claim 5,
Further comprising a sensor for measuring the rotational speed of the rotor, wherein the control unit variably controls the rotation of the drive motor by comparing the rotational speed of the other rotor with the rotation control of the drive motor and the control. Generator rotor rolling system. The method of claim 1,
The manual support is a generator rotor rolling system, characterized in that the support position of the manual support roller and the second stabilizer roller can be adjusted in the range of 0 ~ 150mm with respect to the axial direction of the rotor.

Images